Refrigeration



May 8, 1945.

w. T. HEDLUND.

REFRIGERATION Filed June 15, 1940 3 Sheets-Sheet 1 May 8, 1945. I w. T. HEDLUND REFRIGERATION 3 Sheets-Sheet 5 Filed June 15, 1940 TOR. v

MTTORNEY.

Patented May 8, 1945 s PATENT OFFICE REFRIGERATION William '1. Hedlund, New Rochelle, N. Y., assignor to Serve], Inc., New York, N. Y.,.a corporation of Delaware Application June 15, 1940, Serial No. 340,674

5- Claims.

My invention relates to refrigeration, and mor particularly to preservation of foodstufl's in household refrigerators. k

The butcher, the grocer, the dairyman, the vegetable and fruit vendor, and theiceman each has his particular problem of refrigeration in connection with making ice or preservation of foodstuffs. Freezing water into ice and preserving frozen food products requires freezing temperatures. On the other hand, natural fruits and many vegetables are spoiled by freezing. Meats should be kept at low temperatures but should not become dry. Vegetables also should not become dry but do not need to be preserved at such low temperatures. All of these problems converge in household refrigerators, in which the products of the butcher and grocer, the fruit and vegetabl vendor, and the dairyman are placed for s'afekeeping in the home, and in which ice is made and frozen foods ar kept. The making of ice requires freezihg temperatures, and freezing temperatures cause drying of air and drying of meat and vegetables contacted by the dry air.

Cool dry air is required for proper preservation of a number of products as, for example, bottled goods, eggs, and skin fruits. But dry air causes deterioration of other roducts such as meats and vegetables. A householder is confronted with these problems when placing foodstuffs in his rei'rigerator and therefore requires a refrigerator having provision for storage of foodstuffs under different humidity conditions.

For making ice and preserving frozen food products, household refrigerators are provided with freezing elements for maintaining one or the invention, I provide, in a refrigerator storage compartment, a freezing element, and a separate inner compartment refrigerated so that the temperature is low for preservation of meats and the like, and the humidity is relatively high so'that the refrigerated meat does not become dry. Cooling of the high humidity compartment is effected by an evaporator or cooling unit of refrigeration apparatus which also effects coolin of the storage space proper. The high humidity compartment is provided with its own door or other means to permit access thereto and also to substantially prevent flow of air from such high humidity compartment into the storage space proper and from the latter into the high humidity compartment. 'In order to obtain efficient utilization of the refrigerator storage. space, the low temperature-high humidity compartment is preferably arranged alongside the cooling unit which effects cooling of the storage space proper. Thus,

the freezing zone and low temperature-high humidity cooling zone may be disposed at the same level at the upper part of the storage space whereby the intermediate region of the storage space forms a relatively wide and unobstructed space serving as a low temperature cooling zone of reduced humidity. Closed ,or substantially closed containers are preferably disposed at the bottom part of storage space proper to provide more ice tray compartments at freezing temperature. Water vapor condenses out of air in the refrigerator and freezes to ice or frost on these freezing elements, resulting in dry air in the refrigerator. For this reason household refrigerators have been provided with. vegetable pans which are closed containers for vegetables and the like in which the air is kept out of circulation and therefore maintained at a higher humidity. Closed containers of'this type have also been provided for storage of meat products. But these containers have been refrigerated indirectly through the medium of air in the refrigera'tor.

It is an object of my invention to provide a household refrigerator that affords the user the desired selectivity of refrigerator zones, preferably in a single general storage space having different humidity conditions for proper preservation of different foodstuffs. In accordance with a cooling zone of higher humidity and tempera-- ture, as for certain vegetables.

The low temperature-high humidity'compartment may be cooledby transferring cooling effect thereto from an-evaporator structure or cooling unit which is operated below the freezing temperature of water. In such case heat isgtransferred in such a manner thatthe low temperature-high humidity compartment is cooled'to a low temperature but not below the freezingtemperature of water, so that frost formation and congealing of moisture in the high humidity compartment is avoided. I preferably employ a cooling unit or evaporator structure of suitable refrigeration apparatus having a low temperature cooling element and a higher temperature cooling element. The low temperature cooling element operates below the freezing temperature of water, and the higher temperature cooling element operates at a higher temperature of which at least a portion thereof is substantially at or above the freezing temperature of water. 7 In accordance with my invention, in order to make certain that the high humidity compartment will always be cooled to a temperature aJbove-that of freezing, a heat transfer system is provided wherebycooling effect is transmitted thereto from 1 the portion of the higher temperature cooling element which is adapted to operate substantially that no formation of frost will take place in the high humidity compartment which would tend to reduce the humidity therein.

It is another object of the invention to arrange the freezing zone and low temperaturehigh humidity zone in such a manner that the compartment forming the low temperature-high humidity zone serves as a baflle to cause circulation of air to take place naturally in'th storage space proper in a definite manner. In the present embodiment which is illustrative of the invention. a third compartment is provided alongside the freezing and low temperature-high humidity compartments, with such third compart ment being cooled by air circulating in the storage space proper and in the path of flow of such circulating air at a region-where its temperature is the highest.

It is a further object of the invention to provide a plurality of compartments which form several cooling zones alongside of each other at the upper part of a refrigerator storage space with a defrosting or drip tray located beneath the compartment serving as a freezing zone, and a drain conduit for draining condensate from the low temperature-high humidity compartment to the tray. The several compartments are preferably provided with a front baille plate having doors to permit access into the compartments with such baflle being arranged to conceal the defrosting tray from view. Suitable mechanism may be provided to lower the defrosting tray from its normal position and also move the latter forward beneath the baffle plate to facilitate handling of the tray. The mechanism just mentioned may be provided with a readily accessible operating part so that the tray can readily be lowered from and moved back to its normal position beneath the freezing compartment at the rear of the front baflie plate.

The invention, together with the above and other objects and advantages thereof, will be more fully understood from the following description taken in conjunction with the accompanying drawings forming a part of this specification, and of which; I

Fig. 1 is a front elevation of a refrigerator cabinet embodying the invention, the door of the cabinet being in its open position;

Fig. 2 more or less diagrammatically illustrates a refrigeration system and a side vertical sectional view of the refrigerator cabinet shown in Fig. 1 and taken on line 2-2 of Fig. 3;

Fig. 3 is a vertical sectional view taken on lines 3-3 of Figs. 2 and 4 to illustrate more clearly the arrangement of parts in the refrigerator storage space;

Fig. 4 is a horizontal sectional view taken on line 44 of Fig. 3;

Fig. 4a is a fragmentatry sectional view'taken on line 4a4a of Fig. 3;

Fig. 5 is a sectional view taken on line 5-5 of Fig. 3 to illustrate more clearly theinechanism for lowering and raising the defrosting or drip tray located beneath the ice freezing compart- Fig. 7 is a fragmentary sectional view taken on line 1-1 of Fig. 3;

Fig. 8 is a sectional view similar to Fig. 5 with I the defrosting or drip tray in its lower position; Fig. 9 is a fragmentary sectional view similar to Fig. 3 and taken on line 9-8 of Fig. 10 to illustrateanother embodiment of the invention and;

Fig. 10 is a vertical sectional view taken on line III-I0 of'Fig. 9.

Referring more particularly to Figs. 1 and 2, I have shown the invention embodied in a refrigerator comprising. a cabinet Ill having an inner metal shell I I arranged to be supported within an outer metal shell I2 and insulated therefrom with. any suitable insulating material I 4. The inner shell I I forms a thermally insulated storage space I5 into which access may be had by a door I6 hinged to the front of the cabinet. The storage space I5 is provided with a plurality of shelves I! for supporting food products and the like which are to be maintained at a low temperature. In the bottom part of storage space I5 are disposed a plurality of vegetable trays or fresheners 9,

such trays being slidably supported at the underside of bottom shelf I! which is solid and imperforate and serves as a cover for thevegetable fresheners when thelatter are pushed into the storage space I5. 3

Within the storage space I5 are disposed a freezing element and a cooling element which to- -in water, for example, and also an auxiliary agent or inert gas, such as hydrogen.

the lower part thereof through a conduit 26. Liquid in cooling unit I8 evaporates and diffuses into the inert gas to produce a refri erating effect with consequent absorption of heat from the surroundings. The rich gas mixture of refrigerant vapor and inert gas, that is, gas rich iii-refrigerant, flows from' the upper part of cooling unit I8 through a conduit 21, an inner passage 28 of a gas heat exchanger 29, and a conduit 30 into the lower part of absorber 2 I.

In absorber 2I the-rich gas mixture flows counter-current to downwardly flowing weak absorption liquid which enters through a conduit 3|. The absorption liquid absorbs refrigerant vapor from the inert gas, and inert gas weak in refrigerant flows from absorber ZI through a conduit 32, outer passage 33 of gas heat'exchanger 29, and conduit 26 into the lower part of cooling unit I8.

Absorption liquid enriched in refrigerant-flows from the lower part of absorber 2| through a conduit 34, outer passage of a liquid heat ex-' changer 35, and a conduit 36 into the generator I9. Liquid is raised in the generator by a thermosiphon tube 31 and flows back to'the generator through standpipe 23. Refrigerant vapor expelled out of solution in generator 49, together with refrigerant vapor entering through thermosiphon tube 31, flows upwardly through standpipe 23 and conduit. 24 into the condenser 26, as

explained above.

The absorption liquid from which refrigerant thermosiphon tube 31.

Heat liberated with absorption of refrigerant -wapor in absorber 2I- is transferred to a suitable cooling medium which circulates through a coil "arranged in heat exchange relation with the absorber.

The outlet end of condenser 26 is connected by a conduit 46, vessel 4|, and conduit 42 to the gas circuit, so that any inert gas which may pass through the condenser can flow into the gas circuit. Refrigerant vapor not liquefied in con denser 26 flows through conduit .to displace inert gas in vessel 4| and force such gas through conduit 42 into the gas circuit. The effect of "forcing gas into the gas circuit in this manner is to increase the total pressure in thesystem to insure condensation of refrigerant vapor in condenser 20.

The circulation of gas in the gas circuit in.- cludingcooling unit l8 and absorber 2l'ls due to the difference in specific weight of the columns of inert gas rich and weak, respectively, in refrigerant vapor. Since the rich gas is heavier than the weak gas, a force is produced or .developed within the system tocause flow of rich gas to the absorber 2| and flow of weak gas toward evaporator unit I. I

The cooling unit i8 includes an 'upper cooling element or coil 43 and a lower freezing element or coil 44 whichare connected in series relation. Liquid refrigerant entering the upper coil 43 through conduit 25 flows through this coil and then through the lower coil 44 in counter-flow to inert gas which flows upward through the evaporator.

The upper cooling element or'coil 43 is formed with a plurality of heat transfer fins 45 to provide a relatively extensive heat transfer surface for cooling air in storage space l5. The lower freezing element or coil 44 is arranged in thermal exchange relation with a shell 46 having a plurality of compartments, as shown most clearly in Fig. 3,

j 44 of cooling unit l8 in storage space IS, the rear --insulated wall of the space is provided with an opening to'receive a removable wall-section 48 as shown most clearly in Figs. 2 and 4. The conduits connecting evaporator l8 and the other parts of the refrigeration system extend through the removable wall section 48. These connections include conduits 25, 26 and 21, and also a' drain conduit 49 to permit flow of unevaporated liquid from evaporator IE to the inner passage 28 of gas heat exchanger 29;

- The cooling element 43 and freezing compartrment 46 are located in the upper left-hand corner of storage space i5. Adjacent to and alongside the cooling element and freezing compartment 46 is'arranged a-housingor casing 50, as shown most clearly in Figs. 3 and 4. The casing 56 may be supported in position in space H in any suitable manner. As shown, angle brackets 5| may be secured to the bottom of the casing 50 at the rear' thereof, and an angle bracket 52 may be secured to the top of the casing at the forward part thereof, The brackets 5| and 52- may be'removably secured to the rear and top wall of inner shell I I, as indicated at 53 and 54, respectively.

The casing 50 forms a low temperature-high a humidity compartment 55 which is arranged to be cooled by upper cooling element 43 with the aid of a heat transfer system. The left-hand side wall of the casing 50 is employed as a part of the heat transfer system. To this side wall is secured a metallic sheet 56 which is slightly less in height 'andsubstantially the same in length as the side wall, as shown most clearly in Figs. 3, 4 and 7.

The metallic sheet 56 is provided with a plurality of spaced depressed portions 51 which-may be welded to the side Wall of casing 50 to maintain the wall and sheet in spaced relation and provide a'fluid passage therebetween, and the peripheral edges of the sheet are hermetically'secured, as by welding or brazing, to the side wall.

The upper part of sheet 56 is connected by a conduit or tube 58 to a crescent-shaped hollow member 59. The hollow member 59 is substantially the same in length as a straight conduit section of the upper cooling element 43, as shown in Fig. 4. The hollow member is removably secured in close contact with the upper cooling element 43 by straps 60 and suitable fasteners 6|. The hollow member 59 is preferably formed of material which is somewhat resilient so that it will conform to the shape of the conduit section when it is pressed against the latter by the straps '68 and fastener 6|.

The hollow member 59, conduit 58, and the metallic sheet 56 and side wall of casing 50 to which it is secured form a vaporization-condensation element which is partly filled with a suitable volatile liquid. The volatile liquid, such as ethyl chloride, evaporates in the evaporation portion formed by the sheet 56 and side wall to which it is secured and takes up heat, thereby effecting cooling of compartment 55. The vapor flows upward through conduit 58 into hollow member 59 which forms a condensation portion of the element and in which the vapor is cooled and condensed by the upper coil' or cooling element 43. The space between the metallic sheet 56 and wall to which it is secured and the size of conduit 58 should be so dimensioned that liquid flows freely by gravity from the condensation portion 59 back to the evaporation portion.

The shell 46 and casing 50 are provided-with a front baifle plate 62 which is supported by the shell and casing in any suittable manner. The front baflle plate 62 extends from one side wall to the opposite side wall of storage space l5, as shown in Figs. 1 and 4, and is provided with a plurality of openings in alignment with the openings at the front of shell 46 and casing 50. Doors 63, 64 and 65 are hinged to the front baiile plate the storage space proper and this compartment is cooled by air circulating in storage space l5. As shown most clearlyin Figs. 3 and 4, a shelf 81 of an open or perforated'type may be supported by hooks 88 secured to the front bailie plate 82 and walls of inner shell ll, whereby food products and the like may be stored in compartment 88.

The door 84 for middle compartment 55 is provided with a gasket 5511 which may be formed of rubber or the like, as shown in Fig. 4a. The gasket 55a is held in place by metal strips 84a which are riveted or otherwise secured to the flanges of door 84.- The door 88 for shell 45 is also provided with a gasketsimilar to the gasket 55a for compartment 55. A drain conduit 88 is connected to the lower part of casing 88 to permit condensate to drain from the high humidity compartment 55 to a drip or located beneath shell 48.

As shown most clearly in Figs. 1 and 5, the front baille plate 82 extends below the tray 18 so that the tray is hidden from view when it is in its upper or normal position beneath the shell 48.

Suitable mechanism is provided to lower and raise tray 18 between the positions shown in Figs. 5 and 8. When access to tray 18 is desired, it is readily lowered and moved forward underneath the lower edge of front baflle plate 82 from the position shown in Fig. 5 to that shown in Fig. 8. Referring more particularly toFigs. 3, 5 and 8, the mechanism provided includes a three-sided frame having spaced U-shaped side channels 1| and 12 and a U-shaped'rear channel 18 connecting the side channels II and 12. The frame is open at its forward end and the U-shaped channels 1|, "and 18 form a groove to receive the defrosting tray 18 5 to the right, so that the upper notch 88'is ineffective to hold operating lever 8| in the upper position shown in Fig.5. The handle 85 is then lowered in slot 84, and, when the lever is in the position shown in Fig. 8, the handle can be moved to the left so that the lower notch 81 willbe effective to keep lever 8| in its lower position. When lever is moved from the position 'shown in Fig.

5 toward the position shown in Fig.8, link 88 causes clock-wise rotation of bell crank 18 until the longarm thereof is moved to a straight vertical position". The link 18 at the left-hand side of shell 48 and the links 14 at the opposite side thereof also move to straight vertical positions, whereby the frame formed by the side channels 1| and 12 and rear channel 18 moves downward and forward with the forward part of the frame passing beneath and in front of the baflle 82, as shown in Fig. 8. With the tray supporting frame in its lower position, the tray 18 may be moved forward along the side channels 12 to permit access thereto. a When the tray 18 is moved downward and forward from the position shown in Fig. 5 to the position shown in Fig. 8, the coil spring 88 is position againstthe tension of coil spring 83.

flanged edges of the side walls of tray 18. As

shown most clearly in Figs. 2 and 3, the forward and rear parts of side channel 12 at the rightvhand side of shell 48 are pivotally connected by links 14 to studs 15 fixed to a side wall of casing 58. The forward part of the side channel 1| at the left-hand side of shell 48 is pivotally connected by a link 18 to a stud 11 secured to aside wall of inner shell II, as shown in Figs. 3, 5 and" nected by a link 88 to an intermediate part of an operating lever 8|.

The rear end of lever 8| is pivotally connected to a stud 82 secured to the side wall of inner shell II, as shown most clearly in Fig. 3. One end of a coil spring 83 is connected to stud 82 and the opposite end thereof is connected to the outer end of the long arm of hell crank 18. The operating lever 8| extends through a vertically extending slot 84 in the front balile 82, as shown most clearly in Fig. 6, and the extreme forward end is provided with a horizontal handle portion 85. The slot 84 is notched at its upper and lower ends at 86 and 81, respectively, to keep the tray 18 either in its upper or lower position, as, will be described presently.

With the handle 85 in'the upper notch 88, as shown in Fig. 6, the parts'of the mechanism for raising and lowering tray 18 aredn the position shown in Fig.5, with the tray 18 in its upper inaccessible position and hidden or concealed from .view at the rear of front baflle plate 82. When access to tray 18 is desired handle." ismoved After the tray 18 is pushed rearwardly alongthe side channels 1| and]! until the rear part thereof is against the rear channel 18, the handle 85 may be moved to the right to release operating lever 8| from the lower notch 81 to effect raising of tray 18 to its upper concealed position. In order to reduce the amount of manual efiort required to raise the tray 18, the coil spring 88 is made sumciently strong so that it will tend to pull bell crank 18 in a counter clock-wise direction, and this upward pull exerted by the spring, supplemented by a relatively small lifting force on handle 85, will be effective to raise operating lever 8| to its upper position where the handle 85 may be moved to the left, so that the upper notch 88 will receive the forward part of the operating lever and hold the latter in its upper position.

In Figs. 9 and IO-I'have illustrated another embodiment of the invention in which a heat con-' ductive path is provided betweenthe shell 48 of low temperature cooling element 44 and a shell or housing 58a forming the high humidity compartment 55. The shell 50a maybe supported in the upper part of storage space l5 by brackets 5| and 52 in the same manner as shell 58 in Figs.

4 and 5 and described above.. The left-hand side wall of shell 58a is formed with a plurality of butsurfaces'ofthe caps88 are pressed against the I shell 48 and in good thermal contact with the latter. The shell 58a, buttons 88 and shell 48 provide a heat conductive path whereby heat is taken up by shell 58a to eifect cooling of compartment '55 and such heat is rejected or given up to low temperature cooling element 44.

During operation, air cooled by thermal transfer with the heat transfer fins 45 and coil forming upper cooling element 43 flows downward past shell 48 of freezing element 44 where additional cooling of air is efiected. It is to be understood, however, that the heat transfer fins and coil ofupper cooling element 43 are provided primarily for cooling air, and that the shell 48 oflower freezing element 44 is provided with limited heat transfer surface to assist in effecting air cooling in storage space IS. The cooled air flows downward in storage space l from cooling elements 43 and 44 to replace warmer air which flows upward and passes through compartment 65 and thence across the top of compartment 55. This natural circulation of air in the caused to flow overthe top of the compartment 55 and over the surfaces of heat transfer fins 45 and upper coil forming the upper cooling element 43.

Since the shell 45 and coil associated therewith constitute a freezing element 44 which operates below the freezing temperature of water, water vapor is condensed out of the air flowing over the surfaces of shell 45 and congeals on the latter. Due to such removal of water vapor from the air, the humidity in storage space I5 is reduced. The regions of the storage space directly influenced and cooled by the air circulating over the cooling elements 43 and 44 may be referred to as the storage space proper and includes the compartment 66 and the intermediate regionand attendant formation of frost on shell 45.

Since the upwardly flowing air is the warmest air in this cooling zone, the compartment 65 provides an auxiliary low humidity region which is at a slightly higher temperature than the intermediate region of storage space 15.

The vegetable trays or fresheners 9 are closed by the bottom shelf l1, so that these trays provide a cooling zone having ahigher humidity than in the zone formed by storage space l5. By closing the trays or fresheners 9 so that substantially no flow of air can take place between the spaces within trays 9 and storage space I5, the relatively dry air circulating in the storage space cannot extract moisture from vegetables and the like which are placed in the trays 9.

The door 64 closes off the compartment 55 so that substantially no flow of air takes place between this compartment and storage space I5. The compartment 55 provides a cooling zone which is maintained at a higher humidity and at a lower temperature than storage space IS. The low temperature-high humidity cooling zone formed by compartment 55 is always maintained at a temperature above 32 F. to prevent congealing of moisture and formation of frost therein. In the embodiment in Figs. 3 and 4, this is accomplished by operating the entire upper cooling element 43, or at least the portion thereof in thermal contact with condensation portion 59, at a heat transfer circuit associated therewith, this o spectively. In such case, the casing 50 may be provided with threaded openings to receive the storage space l5 by loosening the fasteners 6| the transfer member or medium. By so designing the freezing system that condensation portion 59 of the vaporization-condensation circuit is approximately at or above 32 Fyunder all operating conditions of the refrigeration apparatus, the metal plate 56 and cooperating metal wall of casing 50, which together form the vaporization portion of the heat transfer element, will always be above 32 F. so that non-freezing refrigeration of compartment 55 is effected. I

Similarly, in {the embodiment in Figs. 9 and lo, the cooling effect is transmitted from shell 46 to housing 50a through the buttons or caps 88, the number and area of which can be designed so that housing 50a willbe maintained at .a lower temperature than storage space 15 proper but at a tempertaure above 32 F. With the temperature of compartment 55 above the freezing temside wall of inner shell H and by studs 75 to shell 50 and not connected to the cooling unit or evaporator l8, the latter may be removed from and removing the crescent-shaped condensation member59 from upper cooling element 43. When this is done, the cooling unit l8 including removable wall part 48 can be moved rearwardly with other parts of the refrigeration apparatus. Likewise, if it is desired to remove shell 50 and the may be done by loosening the fasteners 6| to disconnect the condensation member 59 from the upper cooling element 43 and disconnecting shell 50from the brackets 5| and 52 at 53 and 54, re-

studs 15, so that these parts will also be removable from the shell 50 to permit removal'of the latter from storage space l5 together with the heat transfer circuit. It will be seen, therefore, that the cooling unit or evaporator l8 of the refrigeration apparatus may be removed from storage space l5 independently of shell 50 and the heat transfer circuit associated therewith, and that the shell 50 and its associated heat transfer circuit may also be removed from storage space l5 independently of the cooling unit or evaporator N3 of the refrigeration apparatus.

While I have shown and described several embodiments of my invention, it will be apparent to those skilled in the art that modifications and changes maybe made without departing from the spirit and scope of the invention. Thus, the natural circulation of air may be augmented by forced draft. I therefore do not wish to be limited to the actual structure shown in the drawings and described in the specification, and aim in the following claims to cover all modifications and changes which fall within the true spirit and scope of the invention.

What I claim is:

1. In a refrigerator having a general insulated storage space, a primary evaporator in the upper part of said storage space, a self-contained high humidity chamber of relatively low temperature in said space alongside said primary evaporator, said chamber having a metal wall, a second evaporator partly formed by said wall, a condenser in heat exchange relation with the first-mentioned evaporator, and a connection between said second evaporator and said condenser.

2. In a refrigerator having a general insulated food space having a plurality of openwork shelves to permit air circulation and store food, a primary evaporator disposed therein for cooling air therein, said evaporator being disposed insaidv space to cause'air to flow by natural convection in a defined stream including downflow and upflow-currents. the evaporator being in the downfiow current, and a member dividing the downflow current from the upfiow current comprising a substantially closed high humidity chamber.

3. In a refrigerator having a general insulated food space, a'primary evaporator disposed therein for cooling air therein, said evaporator being disposed insaid space to cause air to fiow in a defined stream including downflow and upfiow her having openings to permit access to each M said compartments, closure members for the open- 'ings, a heat conductor for transmitting cooling eifect from said evaporator to said first compartment, said heat conductor being so constructed and arranged that air in said first compartment is maintained at a higher humidity than air in' said storage space, and said evaporator being eflectlve to cause natural circulation of air in said storage space whereby air flows downward partment and thence across the top ofthe latcurrents, the evaporator being in the downflow current, a member dividing the downflow current from the upfiow current comprising a substantially closed high humidity chamber of relatively low temperature situated to permit air toflow over the top thereof as well as to the sides thereof,

- and a fixed conductor to transfer a major portion alongside said shell, said evaporator and shell being narrower than said storage space toprovide a third compartment at the opposite side compartments extending from one side to the opposite side of said storage space, said wall memter.

5. A refrigerator including a thermally insulated cabinet, said cabinet having a general food storage compartment, an ice freezing compartment, and a closed high humidity compartment, said ice freezing compartment and said high humidity compartment being located laterally of each other and substantially at the'same level in said general storage compartment, a refrigeration system of the type in which cooling is produced by'evaporation of refrigerant in the presence of an auxiliary fluid, said system including a low temperature cooling element comprising a located above said low temperature cooling element and arranged for cooling air in said general storage compartment, and a heat conductor for transferring heat from said high humidity com- I partment to said high temperature cooling eleof said shell, a front wall member for all of said as ment.

WILLIAM T. HEDLUND. 

